SU1613188A1 - Pneumatic sprayer - Google Patents

Abstract

The invention relates to devices for dispersing liquids containing a solid phase, and can be applied in the chemical industry, for example for drying polymeric materials, and in other industries. The aim of the invention is to reduce power consumption and increase reliability of operation. To do this, a hole is made in the fluid supply nozzle located along the flow of fluid behind the tangential channels. When the sprayer operates, the atomization process is intensified by applying high frequency oscillations of the same frequency to the gas and liquid. 2 Il.

Description

The invention relates to devices for dispersing liquids containing a solid phase, and can be applied in chemical industry, for example, for a day polymeric materials, and in other areas.

The purpose of the invention is to reduce energy. cost and increased reliability.

FIG. 1 shows the spray, incision; in fig. 2 is a section A-A in FIG. one.

The atomizer contains a vortex chamber 1 with tangential channels 2 and 3 tilted towards the bottom and an outlet nozzle 4 and an outlet nozzle 5 installed along the axis of the chamber 1 for supplying fluid with nozzle 6. In channels 2 and 3 there are nozzles 7 to 8. In the side wall of the nozzle 5 A hole 9 was made, located along the supply line behind the tangential channels 2 and 3..

Cruiser 7 works as follows.

The spraying gas is supplied to the nozzles 7 and 8. The gas enters the vortex chamber 1 through tangential channels 2 and 3, which twist it and direct it to the bottom of the vortex chamber 1. In the area between the tangential channels 2 and 3 and the bottom of the vortex chamber 1, the pressure increases. At the same time, the gas flow rate to this zone and the dynamic pressure at the outlet of tangential channels 2 and 3 decrease. The amount of gas from the pressure zone rapidly moves axially towards the nozzle 4, distorting the shape of the swirling jet and leaving behind it a rarefaction zone where the gas flows from the tangential channels 2 and 3 with increased velocity and again creates an area of increased pressure. The frequency of the generated acoustic “-s oscillations depends on the magnitudes, yivia tangent

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Social channels 2 and 3 and the volume of the vortex chamber 1 o To achieve the required level of amplitude of acoustic oscillations, select the angle of inclination of the tangent holes in the range of 15-30.

The main part of the gas moves along the 1-discharge chamber 1. to the nozzle 4, while the other part of the gas in front of the opening 9 enters the liquid nozzle 5, where it mixes with the mixed one. liquid, the gas saturation process being intensified due to the presence of acoustic oscillations. As a result of the interaction of the liquid to be sprayed and the filling gas entering through the opening 9, oscillations superimpose on the liquid, of the same frequency that the spray gas has. At the exit of the gas 4 and liquid 6 nozzles, the gas interacts with the gas-saturated liquid, which leads to disintegration liquid on the drops. Moreover, this process is intensified by the superposition of high-frequency oscillations on gas and liquid of the same frequency.

Compared with the prototype, the proposed device provides a finer spray at the same energy consumption, which allows to obtain a product of the required dispersion at lower energy consumption. In addition, the continuous operation time of the sprayer without cleaning the liquid nozzle is increased, which increases its reliability.

Claims (1)

Invention Formula A pneumatic raspipitel containing a vortex chamber with tangential channels inclined towards the bottom and an outlet nozzle and a pipe fitting installed along the chamber axis with a nozzle that differs in that, in order to reduce energy consumption and increase reliability of operation, a hole is made in the liquid supply nozzle , located in the course of the fluid supply for tangential channels.  Spreading  h h x 7 ± . h // //// G ////// L I w / I Causticity . Dissipating gas FIG. 7 FIG. 2